BARC/1994/E/012 > JO o REMOVAL OF RADIORUTHENIUM FROM ALKALINE INTERMEDIATE LEVEL RADIOACTIVE WASTE SOLUTION : A LABORATORY INVESTIGATION by S. K. Samanta and T. K. Theyyunni Process Engineering and Systems Development Division 1994 BARC/1994/E/0I2 o GOVERNMENT OF INDIA J ATOMIC ENERGY COMMISSION u < so REMOVAL OF RADIORUTHENIUM FROM ALKALINE INTERMEDIATE LEVEL RADIOACTIVE WASTE SOLUTION : A LABORATORY MVESTiGATiON by S.K. Samanta and T.K. Theyyunni Process Engineering and Systems Development Division BHABHA ATOMIC RESEARCH CENTRE BOMBAY, INDIA 199* BARC/1994/E/012 BIBLIOGRAPHY DESCRIPTION SHEET FOR TECHNICAL REPORT (as per IS « 94OO - 198O) 01 Security classification : Unclassified 02 Distribution :: External 03 Report status : New 04 Series : BARC External 05 Report type s Technical Report 06 Report No. s BARC/1994/E/012 07 Part No. or Volume No. t 08 Contract No. : 10 Title and subtitle e Removal of radiorutheniutn from alkaline intermediate level radioactive waste solution t a laboratory investigation 11 Collation s 29 p., 3 figs., 7 tabs. 13 Project No. a 20 Personal author (s) t S.K. Saaianta; T.K. Theyyunni 21 Affiliation of author (s) s Process Engineering and Systems Development Division, Bhabha Atomic Research Centre, Bombay 22 Corporate author(s) t Bhabha Atomic Research Centre, Bombay-400 065 23 Originating unit : Process Engineering and Systems Development Division, BARC, Bombay 24 Sponsor(s) Nime t Department of Atomic Energy Type : Government 30 Date of submission t May 1994 31 Publication/Issue date June 1994 contd...(ii) (ii) 4O Publisher/Distributor : Head, Library and Information Division, Bhabha Atomic Research Centre, Bombay 42 Farm of distribution t Hard copy 50 Language of text : English 51 Language of summary t English 52 No. of references : 10 refs. 53 Gives data on : 60 Abstract :Various methods were investigated in the laboratory for the removal of radioruthenium from alkaline intermediate level radioactive waste solutions of reprocessing plant origin. The methods included batch equilibration with different ion exchangers and sorbents, column testing and chemical precipitation. A column method using zinc-activated carbon mixture and a chemical precipitation method using ferrous salt along with sodium sulphite were found to be promising far plant scale application. 70 Keywords/Descriptors : INTERMEDIATE-LEVEL RADIOACTIVE WASTES; RADIOACTIVE WASTE PROCESSING; PUREX PROCESS; PRECIPITATION; IRON HYDROXIDES; ZEOLITES; 0R6ANIC ION EXCHANGERS; RESINS; ZINC; ACTIVATED CARBON; DISTRIBUTION FUNCTIONS; DECONTAMINATION; RUTHENIUM 1O6; RUTHENIUM 103; TRACER TECHNIQUES; PH VALUE; RHODIUM 106; EFFICIENCY 71 Class No. : INIS Subject Category t E51OO; B162O 99 Supplementary elements : REMOVAL OF RADIQBOTHBHIOM FROM ALKALINE INTERMEDIATE LEVEL RADIOACTIVE WASTE SOLUTION : A LABORATORY INVESTIGATION S.K.Samanta and T.K.Thoyyunni Process Engineering and Systems Development Division Bhabha Atomic Research Centre Trombay, Bombay 400 085 1. INTRODDCTIOH Because of its complex chemistry and high radioactivity, Ru-106 is one of the major radionuclides of concern in aqueous radwastes generated at spent nuclear fuel reprocessing plants. In the PUREX flowsheet, dissolution of the spent fuel in nitric acid leads to the conversion of fission product ruthenium into numerous complex species containing the nitrosylruthenium (Ru-NO) group, which is very stable and persists through the various processing stages. Such complexes in nitric acid solution can be represented by the general formula [1] : [RuNO(NO3) (NO2)y{OH) (H2O) - - . ]3"x"5r"z x 2 5 x y a Depending on the number and type of ligands attached to the RuNO group, the complex species may be cationic, neutral or anionic in nature. In this report, we are concerned with the effective removal of Ru-106 from intermediate level aqueous radwastes. Large volumes of such wastes generated at spent fuel reprocessing plants are presently stored in underground carbon steel tanks. These waste solutions are alkaline and have a high concentration of dissolved salts (mainly NaN03>. The major radioisotope present in these solutions is Cs-137 (tj/2 = 30 yrs). Other radionuclides present include Sr-90 (tjy£ = 28 yrs) and Ru-106 (ti/2 = 1 yr), the quantity of the latter depending upon the storage period of these wastes because of its relatively short half life. As part of a programme to formulate a suitable treatment scheme for the alkaline salt loaded IL waste solutions, an ion exchange process has already been developed and demonstrated for the selective removal of radiocesium from these solutions [2,3]. The process utilises the high selectivity of a RESORCINOL- FORMALDEHYDE POLYCONDENSATE RESIN (RFPR) [4,5] for cesium from alkaline solutions even in the presence of large quantities of sodium ions. When Sr-90 is also present, it is possible to remove it using a chelating resin containing iminodiacetic acid functional groups. The present work deals with the results of laboratory investigations on developing a suitable method for removal of Ru-106 which, along with its daughter Rh-106, becomes a major contributor to gross (3 activity after removal of radiocesium and radiostrontium. The nature of ruthenium species when acid-PUREX waste solutions are neutralised with alkali is not known with certainty. It appears that partial or complete removal of the nitrato or nitro groups by hydroxide groups in alkaline solutions will result in radioruthenium remaining as species that are either soluble or colloidal in nature. Because of the difficulty in simulating ruthenium species that are actually present, most of the work reported here has been done with a real waste solution of reprocessing plant origin. Some initial results using a simulated test solution are also included for the sake of comparison. 2. EXPERIMENTAL DETAILS 2.1. SCREENING OF SORBENTS AND ION EXCHANGERS A number of sorbents and ion exchangers were used in this investigation for possible uptake of radioruthenium. While some of these were commercial, products, others were prepared in the laboratory. The details of the preparation of the materials, however, are not included in this report. 2.1.1. Tests with Simulated Waste Solution Initially, a number of sorbents and ion exchangers were tested with a simulated waste solution containing 1.0 M NaNOy and 0.1 M NaOH with Ru-103 as tracer for ruthenium. The ruthenium in this tracer was present as the simple Ru(III) ion. For equilibration, 50 ml of the test solution was equilibrated with 0.1 g of the sorbent/ion exchanger for 24 hours. The Ru-103 activity in the solution before and after equilibration was determined using a Nal(Tl) gamma scintillation counter assembly. 3 The distribution coefficient, K^, defined as the ratio of the ruthenium activity per gram of the sorbent/ion exchanger to the ruthenium activity remaining per ml of the solution at equilibrium, was calculated from the following equation '• C - C V t f K = . - , ml/g ...(1) d Cf W where C^ and Cf are the activities (cpm/ml) of Ru-103 in the solutions before and after equilibration, V is the volume of equilibrating solution (50 ml) and W is the mass of sorbent/ion exchanger taken (0.1 g). The results of tests using the simulated waste solution are shown in Table 1. 2.1.2. Tests with Actual Waste Solution The actual waste solution used in these experiments was the effluent obtained after removal of most of the major radionuclide Cs-137 from an intermediate level alkaline waste stream of reprocessing plant origin, using an ion exchange process based on a RESORCINOL FORMALDEHYDE POLYCONDENSATE RESIN (RFPR) developed in the laboratory [2]. Ru-106 was the major radionuclide present in this solution after removal of radiocesium. The composition is shown in Table 2. In this case, 10 ml of the waste solution was used for equilibration with 0.1 g of the sorbent/ion exchanger for 24 hours. In addition to tests with the highly alkaline original solution, equilibrations were also done with the waste solution adjusted with nitric acid to variuos lower pH values. Prolonged equilibration periods (72 hours) were also provided for some of the tests. For all tests with actual waste solution, the uptake of radioruthenium was monitored by measuring the gross gamma activity of the solutions. Since Cs-137 activity was much lower compared to Ru-106, the reduction in gross gamma activity was taken as a conservative estimate of the uptake of radioruthenium. The results of equilibration tests with sorbents/ion exchangers using actual waste solution are given in Tables 3-5. 2.2. TESTS WITH ZINC-ACTIVATED CARBON 2.2.1. Batch Tests A mixture of zinc metal powder (2 g) and coconut chell activated carbon (2 g) was used in this test. The waste solution was adjusted to pH 2.0 with nitric acid and the zinc-activated carbon mixture added to it. The mixture was magnetically stirred daily for 8 hours and then left overnight. Samples (1 ml) of the solution were drawn periodically through a sintered disc filter tube and counted for gross gamma activity to determine the Decontamination Factor (DF) which is defined as the ratio of activities (cpm/ml) before and after equilibration with zinc- activated carbon. The results are given in Table 6. 2.2.2. Column Tests A glass column with PTFE stopcock and sintered disc support was used for filling the zinc-activated carbon mixture. Special care was taken to ensure that the zinc and activated carbon formed an intimate mixture rather than separate layers in the column. The waste feed solution adjusted to pH 2.0 was passed from top to bottom at a flow rate of about 5 bed volumes per hour using a Watson-Marlow peristaltic pump. Effluent samples were collected at regular intervals, filtered and analysed for gross gamma activity. A schematic diagram of the experimental assembly is shown in Fig.l. Two different zinc-activated carbon column tests were done with the same waste solution. The conditions were similar except for a difference in the ratio of zinc to activated carbon and the grade of activated carbon used. Another difference was that the second column test was done after a period of almost two years and since the half life of Ru-106 is one year, this meant that its activity had decayed to 1/4 of its initial value during this period. The results of these two column tests are shown in Fig.2 and Fig.3. 2.3. CHEMICAL PRECIPITATION METHOD A series of experiments were conducted to study the possibility of using chemical precipitation method for ruthenium decontamination. In these tests, ferric/ferrous hydroxides were precipitated in the waste solution in the presence and absence of a reducing agent like sodium sulphite. In each experiment, requisite quantity of chemicals were added to 10 or 20 ml of the waste solution and allowed to equilibrate by shaking on a wrist action shaker. The solutions were then filtered and analysed for